Disclosure of Invention
Based on the above, it is necessary to provide a method and a system for monitoring the state of laboratory equipment based on the internet of things, which are necessary to overcome the defect that in the current cloud data platform, the data display mode is single, and the relationship between the state information and the laboratory equipment can be determined by professional management staff, so that the universality of the cloud data platform is affected.
The embodiment of the application provides a laboratory equipment state monitoring method based on the Internet of things, which comprises the following steps:
obtaining appearance information, function frame information and monitoring information of laboratory equipment based on the Internet of things, wherein the appearance information is appearance scanning information of the laboratory equipment, the function frame information is appearance scanning information of each function module in the laboratory equipment, and the monitoring information is state monitoring information of the function module;
Constructing a first digital twin model according to the appearance information on a first data display body, and constructing a second digital twin model according to the functional framework information on a second data display body;
Building a digital twin body according to the first digital twin model and the second digital twin model;
And generating a state display identifier according to the monitoring information, and labeling the state display identifier on a second digital twin model of the corresponding functional framework information according to the man-machine interaction plug-in.
According to the laboratory equipment state monitoring method based on the Internet of things, appearance information, functional framework information and monitoring information of laboratory equipment are obtained based on the Internet of things, a first digital twin model is built on a first data display body according to the appearance information, and a second digital twin model is built on a second data display body according to the functional framework information. And building a digital twin body according to the first digital twin model and the second digital twin model, generating a state display identifier according to the monitoring information, and labeling the state display identifier on the second digital twin model of the corresponding functional framework information according to the man-machine interaction plug-in. The laboratory equipment is characterized by being a digital twin body, and light state display identification display is realized on the digital twin body by using the man-machine interaction plug-in unit, so that the state monitoring information display form and the universality of the laboratory equipment are provided.
As one of the alternative embodiments, further comprising:
And storing the appearance information, the functional framework information and the monitoring information according to a data processing model, wherein the data processing model comprises a structured data body for storing the monitoring information and an unstructured data body for storing the appearance information and the functional framework information.
As one of the alternative embodiments, the structured data volume is stored based on a lightweight database.
As an alternative embodiment, the process of constructing a first digital twin model on the first data display according to the appearance information includes the steps of:
and constructing a single visual model on a first data display body according to the appearance information as the first digital twin model.
As one of the alternative embodiments, the process of constructing a second digital twin model on the second data presenter according to the functional framework information includes the steps of:
And constructing a data twin model containing the first simulation dynamic interface on a second data display body according to the functional framework information as the second digital twin model.
As an alternative embodiment, the process of constructing a second digital twin model on the second data presenter according to the functional framework information further includes the steps of:
and deploying a second simulation dynamic interface on the second digital twin model by using the man-machine interaction plug-in.
As an alternative embodiment, the process of constructing a second digital twin model on the second data presenter according to the functional framework information further includes the steps of:
And generating display adjustment parameters according to the monitoring information, wherein the display adjustment parameters are used for adjusting the display state of the second simulation dynamic interface.
As one of the alternative embodiments, the method further comprises the steps of:
and acquiring man-machine interaction information and adjusting the state display identifier by using the man-machine interaction plug-in.
The embodiment of the application provides a laboratory equipment state monitoring device based on the Internet of things, which comprises:
The system comprises an information acquisition module, a function frame information acquisition module and a function module, wherein the information acquisition module is used for acquiring appearance information, function frame information and monitoring information of laboratory equipment based on the Internet of things, wherein the appearance information is appearance scanning information of the laboratory equipment, the function frame information is appearance scanning information of each function module in the laboratory equipment, and the monitoring information is state monitoring information of the function module;
The model construction module is used for constructing a first digital twin model according to the appearance information on a first data display body and constructing a second digital twin model according to the functional framework information on a second data display body;
the model combination module is used for building a digital twin body according to the first digital twin model and the second digital twin model;
and the state display module is used for generating a state display identifier according to the monitoring information and labeling the state display identifier on a second digital twin model of the corresponding functional framework information according to the man-machine interaction plug-in.
According to the laboratory equipment state monitoring device based on the Internet of things, appearance information, functional framework information and monitoring information of laboratory equipment are obtained based on the Internet of things, a first digital twin model is built on a first data display body according to the appearance information, and a second digital twin model is built on a second data display body according to the functional framework information. And building a digital twin body according to the first digital twin model and the second digital twin model, generating a state display identifier according to the monitoring information, and labeling the state display identifier on the second digital twin model of the corresponding functional framework information according to the man-machine interaction plug-in. The laboratory equipment is characterized by being a digital twin body, and light state display identification display is realized on the digital twin body by using the man-machine interaction plug-in unit, so that the state monitoring information display form and the universality of the laboratory equipment are provided.
The embodiment of the application provides a laboratory equipment state monitoring system based on the Internet of things, which comprises the following steps:
the appearance scanning device is configured to scan the laboratory device to generate appearance information and also configured to scan each functional module in the laboratory device to generate functional frame information;
The cloud data platform is configured to collect and monitor state monitoring information of the functional module;
the data display device is configured to execute the laboratory device state monitoring method based on the internet of things of any of the above embodiments.
The laboratory equipment state monitoring system based on the Internet of things comprises appearance scanning equipment, a cloud data platform and data display equipment. The data display device obtains appearance information, functional frame information and monitoring information of the laboratory device based on the Internet of things, builds a first digital twin model on the first data display body according to the appearance information, and builds a second digital twin model on the second data display body according to the functional frame information. And building a digital twin body according to the first digital twin model and the second digital twin model, generating a state display identifier according to the monitoring information, and labeling the state display identifier on the second digital twin model of the corresponding functional framework information according to the man-machine interaction plug-in. The laboratory equipment is characterized by being a digital twin body, and light state display identification display is realized on the digital twin body by using the man-machine interaction plug-in unit, so that the state monitoring information display form and the universality of the laboratory equipment are provided.
Detailed Description
For a better understanding of the objects, technical solutions and technical effects of the present invention, the present invention will be further explained below with reference to the drawings and examples. Meanwhile, it is stated that the embodiments described below are only for explaining the present invention and are not intended to limit the present invention.
The embodiment of the application provides a laboratory equipment state monitoring method based on the Internet of things.
Fig. 1 is a flowchart of a method for monitoring a state of a laboratory device based on the internet of things according to an embodiment of the application, as shown in fig. 1, and the method for monitoring a state of a laboratory device based on the internet of things according to an embodiment of the application includes steps S100 to S103:
S100, acquiring appearance information, function frame information and monitoring information of laboratory equipment based on the Internet of things, wherein the appearance information is appearance scanning information of the laboratory equipment, the function frame information is appearance scanning information of each function module in the laboratory equipment, and the monitoring information is state monitoring information of the function module;
s101, constructing a first digital twin model on a first data display body according to the appearance information, and constructing a second digital twin model on a second data display body according to the functional framework information;
s102, building a digital twin body according to the first digital twin model and the second digital twin model;
s103, generating a state display identifier according to the monitoring information, and labeling the state display identifier on a second digital twin model of the corresponding functional framework information according to the man-machine interaction plug-in.
In the embodiment of the application, the laboratory equipment and the functional module perform the prior appearance scanning, and the appearance scanning information is encapsulated into the appearance information and the functional framework information through data. The function modules are sub-modules used for realizing functions in the laboratory equipment, each function module forms the working state of the laboratory equipment according to operation, and state monitoring information of the function modules is display information of a cloud data platform and is used for representing the working state of the laboratory equipment.
According to the scheme provided by the embodiment of the application, the state monitoring information is acquired based on the state monitoring information of the cloud data platform, and the state monitoring information is displayed in the form of another display main body.
The method comprises the steps of constructing a first digital twin model according to appearance information on a first data display body, and constructing a second digital twin model according to functional framework information on a second data display body. The first digital twin model and the second digital twin model are based on different data display bodies, so that the first digital twin model and the second digital twin model can be subjected to differentiation processing conveniently. The data display comprises a first data display and a second data display, and comprises a static data display and a dynamic data display. The static data display body comprises a picture, a three-dimensional static model, a chart and the like, and the dynamic data display body comprises a three-dimensional dynamic model, a dynamic picture and the like.
Preferably, the first digital twin model is based on a dynamic data presenter and the second digital twin model is based on a static data presenter in order to reduce data throughput and avoid additional data processing of appearance information of the laboratory device.
And building a digital twin body according to the first digital twin model and the second digital twin model, and carrying out complete display on laboratory equipment, wherein the first digital twin model and the second digital twin model can be displayed on different layers, so that the cloud data platform can be conveniently docked.
Preferably, the status display identifier of the monitoring information comprises an image, a chart and a text. Preferably, the state display identifier is based on a man-machine interaction plug-in, and the monitoring information is dynamically processed to generate a dynamic state display identifier. The state display identifiers are marked on the corresponding second digital twin models to form corresponding visual display effects.
Preferably, the presentation of the digital twins is based on the same presentation platform as the cloud data platform, e.g. an HTML web page, based on the limitations of the HTML web page, with limitations on the amount of data and image processing capabilities of the digital twins. Based on the method, the universality of the scheme is expanded through the preferred scheme.
As a preferred embodiment, fig. 2 is a flowchart of a method for monitoring a state of a laboratory device based on the internet of things in a preferred embodiment, and as shown in fig. 2, the method for monitoring a state of a laboratory device based on the internet of things in a preferred embodiment further includes step S104:
And S104, storing the appearance information, the functional frame information and the monitoring information according to a data processing model, wherein the data processing model comprises a structured data body for storing the monitoring information and an unstructured data body for storing the appearance information and the functional frame information.
The monitoring information is structured data, and the appearance information and the functional framework information are unstructured data. As shown in fig. 3, the appearance information and the functional frame information are stored separately by a plurality of unstructured data volumes 10, so that the quick and direct call of information with different structure types is facilitated, wherein the data display volume 11 calls data from the unstructured data volumes 10, the man-machine interaction plug-in 21 calls monitoring information from the structured data volumes 20, the data interference of the first digital twin model and the second digital twin model is reduced, the digital twin display is facilitated on a lightweight data display volume (such as HTML), and the data processing amount is reduced.
Preferably, as shown in fig. 3, the structured data volume is stored based on a lightweight database. Such as SQLite database or MYSQL database. Preferably, the MYSQL database is used for storing the structured data body, so that the multithreading operation of the data display body and the man-machine interaction plug-in is facilitated, the light-weight data processing is realized, and the overall data processing capacity is reduced.
The man-machine interaction plug-in selects tools and components capable of interacting and experiencing on a Web interface. Preferably, the man-machine interaction plug-in completes the writing of the state display identifier through JavaScript, and the display of the state display identifier is realized by using HTML and CSS.
As shown in fig. 2, the process of constructing a first digital twin model on the first data display body according to the appearance information in step S101 includes step S200:
s200, constructing a single visual model on a first data display body according to the appearance information as the first digital twin model.
The first digital twin model is a single visual model, does not have the capability of dynamic display and data interaction display, and is fixedly displayed as a bottom layer on a first data display body.
Preferably, as shown in fig. 2, the process of constructing a second digital twin model on the second data presenter according to the functional framework information in step S101 includes step S201:
s201, constructing a data twin model comprising a first simulation dynamic interface on a second data display body according to the functional framework information as the second digital twin model.
And on the basis of the fixed and displayed first digital twin model, the other part of the digital twin body simulates the appearance information of the functional module by the first simulation dynamic interface, including two-dimensional model simulation or three-dimensional model simulation, and gives dynamic actions to the two-dimensional model simulation or the three-dimensional model simulation. The dynamic actions are related to the monitoring information corresponding to the state display identifiers, for example, the parameter changes are displayed on the first simulation dynamic interface through simulation parameter changes of the second digital twin model.
Preferably, as shown in fig. 2, the process of constructing a second digital twin model on the second data presenter according to the functional framework information in step S101 includes step S202:
s202, deploying a second simulation dynamic interface on the second digital twin model by using the man-machine interaction plug-in.
The second simulation dynamic interface of the man-machine interaction plug-in is used for adjusting according to the display adjustment parameters. The data sources and the display layers of the first simulation dynamic interface and the second simulation dynamic interface are different. The first simulation dynamic interface is generated according to digital twin preset information of the data display body, and the second simulation dynamic interface is generated by the man-machine interaction plug-in unit.
Preferably, as shown in fig. 2, the process of constructing a second digital twin model on the second data presenter according to the functional framework information in step S101 includes step S203:
and S203, generating display adjustment parameters according to the monitoring information, wherein the display adjustment parameters are used for adjusting the display state of the second simulation dynamic interface.
And introducing the monitoring information of the structured data body into a man-machine interaction plug-in, and performing data processing to generate display adjustment parameters. And adjusting the display state of the second simulation dynamic interface according to the display adjustment parameters. Taking HTML and CSS as an example, the "button clicked" that takes the display status of the laboratory device function module that characterizes the display adjustment parameters as the function module, the code in the second simulated dynamic interface is as follows:
<!DOCTYPE html>
<html lang="en">
<head>
<meta charset="UTF-8">
<meta name="viewport" content="width=device-width, initial-scale=1.0">
< title > human-computer interaction example title >
<style>
.button {
padding: 10px 20px;
background-color: #007BFF;
color: white;
border: none;
cursor: pointer;
}
.button:hover {
background-color: #0056b3;
}
</style>
</head>
<body>
< Button class = "button" onclick = "alert ('button clicked')" > click me button >
</body>
</html>
On the basis of the digital twin, particularly on the dynamic change of the second digital twin model, the second analog dynamic interface is used for further enriching the visual change of the digital display of the functional module, namely, the visual change is further displayed on the digital twin of the functional module according to the interaction of a user on the man-machine interaction plug-in unit.
Similarly, on the second digital twin model, the monitoring information generates a state display identifier as a layer at a higher layer, the second digital twin model is marked on the corresponding functional framework information, and a user can intuitively determine the state change of the second digital twin model, namely the state information change of the functional module of the corresponding laboratory equipment through the state display identifier, so that state monitoring is intuitively realized.
In the preferred embodiment of the application, the combination of the structured data body, the data display body and the man-machine interaction plug-in unit realizes the digital twin display of the lightweight laboratory equipment state monitoring, can adapt to the monitoring conditions of various laboratory equipment, calculates the load and stores the load by the lightweight data, and is convenient for deployment and maintenance. Based on the method, the state monitoring means of laboratory equipment are enriched.
According to the laboratory equipment state monitoring method based on the Internet of things, appearance information, functional framework information and monitoring information of laboratory equipment are obtained based on the Internet of things, a first digital twin model is built on a first data display body according to the appearance information, and a second digital twin model is built on a second data display body according to the functional framework information. And building a digital twin body according to the first digital twin model and the second digital twin model, generating a state display identifier according to the monitoring information, and labeling the state display identifier on the second digital twin model of the corresponding functional framework information according to the man-machine interaction plug-in. The laboratory equipment is characterized by being a digital twin body, and light state display identification display is realized on the digital twin body by using the man-machine interaction plug-in unit, so that the state monitoring information display form and the universality of the laboratory equipment are provided.
The laboratory equipment state monitoring method based on the Internet of things can be operated on corresponding computer equipment to establish data interaction with a cloud data platform and the like.
As a virtual execution body of the computer device, fig. 4 is a diagram of a laboratory device state monitoring apparatus based on the internet of things according to an embodiment of the application, as shown in fig. 4, and the laboratory device state monitoring apparatus based on the internet of things according to an embodiment of the application includes:
The information acquisition module 100 is configured to acquire appearance information, function frame information and monitoring information of laboratory equipment based on the internet of things, wherein the appearance information is appearance scanning information of the laboratory equipment, the function frame information is appearance scanning information of each function module in the laboratory equipment, and the monitoring information is state monitoring information of the function module;
a model building module 101, configured to build a first digital twin model on a first data display according to the appearance information, and build a second digital twin model on a second data display according to the functional frame information;
a model combining module 102 for building a digital twin from the first digital twin model and the second digital twin model;
The state display module 103 is configured to generate a state display identifier according to the monitoring information, and label the state display identifier on the second digital twin model of the corresponding functional framework information according to the man-machine interaction plug-in.
According to the laboratory equipment state monitoring device based on the Internet of things, appearance information, functional framework information and monitoring information of laboratory equipment are obtained based on the Internet of things, a first digital twin model is built on a first data display body according to the appearance information, and a second digital twin model is built on a second data display body according to the functional framework information. And building a digital twin body according to the first digital twin model and the second digital twin model, generating a state display identifier according to the monitoring information, and labeling the state display identifier on the second digital twin model of the corresponding functional framework information according to the man-machine interaction plug-in. The laboratory equipment is characterized by being a digital twin body, and light state display identification display is realized on the digital twin body by using the man-machine interaction plug-in unit, so that the state monitoring information display form and the universality of the laboratory equipment are provided.
On the whole side of the laboratory equipment, the embodiment of the application provides a laboratory equipment state monitoring system based on the internet of things, fig. 5 is a module structure diagram of the laboratory equipment state monitoring system based on the internet of things in an application embodiment, and as shown in fig. 5, the laboratory equipment state monitoring system based on the internet of things in an application embodiment includes:
The appearance scanning device 1000 is configured to scan the laboratory device to generate appearance information and also configured to scan each functional module in the laboratory device to generate functional frame information;
The cloud data platform 1001 is configured to collect and monitor status monitoring information of the functional module;
the data display device 1002 is configured to perform the laboratory device state monitoring method based on the internet of things of any of the above embodiments.
Before the virtual body of the laboratory apparatus is constructed, the related personnel can scan the laboratory apparatus and scan functional modules within the laboratory apparatus with the appearance scanning apparatus 1000. Taking laboratory equipment as an example of a pressure and temperature measurement calibration instrument, the functional module comprises a pressure measurement instrument, a temperature measurement instrument and a data display instrument.
The data display device 1002 is preferably a smart device including a computer, a notebook computer, a smart phone, or the like. Since the preferred embodiment of the present application can be implemented based on HTML, the data display device 1002 can be implemented using a mobile smart device, such as a smart phone. The state monitoring of the laboratory equipment is completed in a portable and visual way through the man-machine interaction plug-in unit at the mobile side.
The laboratory equipment state monitoring system based on the Internet of things comprises appearance scanning equipment, a cloud data platform and data display equipment. The data display device obtains appearance information, functional frame information and monitoring information of the laboratory device based on the Internet of things, builds a first digital twin model on the first data display body according to the appearance information, and builds a second digital twin model on the second data display body according to the functional frame information. And building a digital twin body according to the first digital twin model and the second digital twin model, generating a state display identifier according to the monitoring information, and labeling the state display identifier on the second digital twin model of the corresponding functional framework information according to the man-machine interaction plug-in. The laboratory equipment is characterized by being a digital twin body, and light state display identification display is realized on the digital twin body by using the man-machine interaction plug-in unit, so that the state monitoring information display form and the universality of the laboratory equipment are provided.
The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.
The foregoing examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.